KR20220008578A - Pcr apparatus comprising compartmentalization chambers having different temperature range each other - Google Patents

Abstract

The purpose of the present invention is to provide a RCR device which comprises: a plurality of chambers having different temperature ranges, wherein the chambers comprise a transfer region in which a sample cartridge comprising a plurality of wells respectively can move; and a fluorescent sensor transfer area in which a fluorescent sensor moves to scan the sample cartridge in a lower part of the chamber in the lowest temperature section among the chambers.

Description

PCR apparatus comprising a plurality of chambers partitioned into different temperature ranges {PCR APPARATUS COMPRISING COMPARTMENTALIZATION CHAMBERS HAVING DIFFERENT TEMPERATURE RANGE EACH OTHER}

This technology is a technology in the field of bio equipment, specifically, it relates to a PCR apparatus that can maximize the efficiency of the thermal cycling process.

Polymerase chain reaction (PCR) technology is continuously developing, and it is a device that can easily process a series of processes such as thermal cycling process and fluorescence detection with a single PCR equipment. Intensification is accelerating. Furthermore, various biodiagnostic technologies capable of continuous and automated processes for a large amount of samples are being developed.

Recently, dd-PCR (digital droplet PCR), a next-generation PCR method that goes beyond real-time PCR and digital PCR (d-PCR), is emerging as a next-generation PCR technology. dd-PCR is a system for amplifying 20 μl of PCR reaction by splitting it into 20,000 microdroplets.

In light of the advanced development of PCR, the technical needs for fluorescence detection, simplification of thermal cycling, and mass processing and continuous processing are amplifying.

The present invention relates to a PCR device capable of efficiently performing thermal cycling only by transferring a sample cartridge carrying a bio sample.

The PCR apparatus according to an embodiment of the present invention includes a plurality of chambers having different temperature sections, and each of the chambers includes a transfer area in which a sample cartridge including a plurality of wells can move, among the chambers. The lower portion of the chamber of the lowest temperature section includes a fluorescent sensor transfer area in which the fluorescent sensor can move and scan the sample cartridge. ,

The PCR apparatus includes a first chamber having a temperature range of 60 to 80 ℃; and a second chamber having a temperature range of 90 to 100°C.

The fluorescent sensor may be disposed under the first chamber to scan the sample cartridge in the first chamber.

An opening/closing means for moving the sample cartridge between chambers is disposed between the plurality of chambers, and the opening/closing means may be made of a heat insulating material.

According to the PCR apparatus of the present invention, by providing a compartmentalized space conversion technology according to the cycling temperature, cycling, the core process of PCR, can be easily accomplished only by transferring the sample, so it is a very useful technology in the future where PCR apparatuses are becoming more intensive. judged

In addition, through the transfer of a sample cartridge including a plurality of wells, a continuous PCR process for a large amount of samples can be made, and therefore it is expected that it will act as a key technological element in the automation of mass examination systems in the future. .

1 is a cross-sectional view conceptually illustrating a fluorescent sensor of a PCR apparatus according to an embodiment of the present invention.
2 is a cross-sectional view conceptually illustrating a PCR apparatus according to an embodiment of the present invention to which the fluorescent sensor of FIG. 1 is introduced.
3 is a cross-sectional view conceptually illustrating a PCR apparatus according to another embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, the technical concept of a fluorescent sensor for a PCR device and a PCR device including the same according to an embodiment of the present invention will be described. However, the following descriptions are exemplary descriptions for concretely explaining the technical idea of the present invention, and it is apparent that the present invention may include various modified embodiments that can be inferred from the descriptions below. In addition, the technical spirit of the present invention can only be interpreted and limited by the following claims, and the technical spirit of the present invention is not limited by the following description.

1 is a cross-sectional view conceptually illustrating a fluorescent sensor of a PCR apparatus according to an embodiment of the present invention.

Referring to FIG. 1 , the fluorescent sensor 100 for a PCR device includes a housing 110 , a support 120 , a light source mount member 130 , a light source 50 , an optical filter 60 , a condensing lens 70 , and a light It includes a sensing member 80 and a light emitting lens 140 . The upper portion of the fluorescent sensor 100 is covered with a transparent substrate 1350, as will be described later, but in reality, the fluorescent sensor 100 moves the transparent substrate 1350 while moving the transparent substrate 1350 on the upper portion of the transparent substrate 1350. Fluorescence excited from samples of a sample cartridge disposed thereon is detected.

A lower portion of the housing 110 is formed of a photodiode mount substrate 112 for mounting the light sensing member 80 . The housing 110 has an open top and is a structure for protecting various components and preventing leakage of light sources to the outside.

The support 120 is a structure for mounting the above-described various light sources 50 , optical filters 60 , condensing lenses 70 , and the like. The support 120 includes an inclined body 124 extending to be inclined from the outer wall of the housing 110 and symmetrically disposed on both sides of the inner wall of the housing 110 . The inclined body 124 has an inclined structure so that the light sources 50 are not vertically incident on the transparent substrate 1350 and radiated in a direction in which both light sources 50 can be condensed.

A light source mounting member 130 for mounting the light source 50 is included on the inclined body 124 . The light source mount member 130 includes light emitting bodies 51 , 52 , 53 , and 54 having a plurality of different wavelengths. In this embodiment, the light emitting bodies 51 to 54 include LED chips. For example, a plurality of LED chips 51 and 52 having different wavelengths are mounted on one light source mount member 130 , and a plurality of LED chips 51 and 52 having different wavelengths are also mounted on the other light source mount member 130 . of LED chips 53 and 54 are mounted. In the present embodiment, a total of four kinds of LED chips 51 to 54 are mounted on each light source mount member 130 including two kinds of LED chips 51 to 54 . However, the type and number of the LED chips 51 to 54 may be changed according to the type or characteristic of the PCR detection target sample.

Each of the LED chips 51 to 54 emits light to be inclined toward the transparent substrate 1350 , and a light emitting lens 140 including a lens is disposed on the light emitting path in order to maximize light emitting efficiency.

A plurality of through holes 122 are formed in the central region of the support 120 . The through hole 122 has the shape of a plurality of line-shaped strips 122 when viewed from above.

In the accompanying drawings, the cross-section of the fluorescent sensor 100 is shown, but the fluorescent sensor actually functions as a kind of surface light source having a plurality of light source arrays along the ground downward direction, and furthermore, the optical filter 60 and the condensing lens ( 70) also has a strip shape. Similarly, the photosensor 80 also has a strip shape in which a plurality of chips are arranged in a line.

Four through-holes 122 are formed in the through-hole 122 to correspond to the type of the LED chip, and a rod-shaped condensing lens 70 is disposed in at least one region inside each through-hole 122 . has been In addition, at the top of the through hole 122, four types of optical filters 61, 62, 63, and 64 for absorbing different types of excited fluorescence, respectively, are disposed. In addition, photosensors 81 , 82 , 83 , and 84 for detecting four types of excitation light are disposed on the lower photodiode mount substrate 112 of the through hole 122 .

As such, the type of wavelength of the LED chips 51 to 54, the type of the optical filter 61 to 64, and the type of the optical sensor 81 to 84 are components that work together to have a document causal relationship.

The fluorescent sensor 100 is configured to simultaneously detect the excitation fluorescence of a plurality of samples labeled with a plurality of fluorescent materials.

2 is a cross-sectional view conceptually illustrating a PCR apparatus according to an embodiment of the present invention to which the fluorescent sensor of FIG. 1 is introduced.

Referring to FIG. 2 , the PCR apparatus 1000 includes a housing unit 1200 divided into a sample transfer area (A) and a fluorescent sensor scan area (B). The housing unit 1200 is spatially partitioned by the above-described transparent substrate 1350 . As the transparent substrate 1350, a glass substrate having excellent transparency may be used for scanning efficiency.

In addition, the PCR apparatus 1000 includes a cartridge transfer unit 1300 and the transfer unit for reciprocating transfer (direction perpendicular to the ground) of the sample cartridge 500 including a plurality of wells 520 in which a plurality of samples are disposed. and a transport rail 1310 for providing a transport path of 1300 . The transfer unit 1300 also performs a protective function of the sample cartridge 500 as well.

Meanwhile, both ends of the housing unit 1200 include fluorescent sensor accommodating units 1400 for accommodating the fluorescent sensor 100 that has been scanned.

The fluorescent sensor 100 may emit a light source while reciprocating in the fluorescent sensor transfer region B, and thus may detect the excited fluorescence in real time. As described above, the fluorescent sensor 100 is designed to have a substantially long bar shape in a direction perpendicular to the ground direction, and the corresponding fluorescent sensor accommodating part 1400 is also designed to have a corresponding structure. Even while scanning through the reciprocation of the fluorescent sensor 100 is performed, the sample cartridge 500 may also be continuously transferred.

Meanwhile, the fluorescent sensor 100 can simultaneously detect fluorescence generated for all samples in the sample cartridge 500 by reciprocally scanning the fluorescent sensor transfer area B once.

3 is a cross-sectional view conceptually illustrating a PCR apparatus according to another embodiment of the present invention.

The PCR apparatus 2000 according to the present embodiment includes a plurality of chamber units 2100 which are adjacent and continuously formed. The chamber units 2100 and 2200 are devices of a scale similar to the PCR device of FIG. 2 described above. The PCR apparatus 2000 includes a first chamber 2100 for performing heat treatment in a first temperature section and a second chamber 2200 for performing heat treatment in a second temperature section.

The first temperature range is a high temperature section of 90 to 100 °C, and the second temperature range is a relatively low temperature section of 60 to 80 °C. The sample cartridge 500 is supported by a separate cartridge support 300 and is thermally cycled while reciprocating between the second chamber 2200 in the low temperature section and the first chamber 2100 in the high temperature section along the transfer rail 1310 . this is done The sample cartridge can detect excitation fluorescence by scanning the fluorescent sensor 100 in real time while reciprocating tens of times, and monitor the detection result in real time. The fluorescence sensor 100 is installed only in the second chamber 2200, which is a low-temperature section, to detect fluorescence.

A first adiabatic opening/closing means 2310 and a second adiabatic opening/closing means 2320 are installed in the inlet region of the sample cartridge and at the boundary of each of the chambers 2100 and 2200, respectively. The adiabatic opening/closing means 2310 and 2320 are means for opening and closing the chamber of the sample cartridge 500, and while the sample cartridge 500 is heat-treated, to prevent thermal equilibrium between the chambers 2100 and 2200 or with the outside. It is made of a material capable of exhibiting an insulating effect for this purpose.

A housing 2250 of the fluorescent sensor 100 may be separately provided in the transport area of the fluorescent sensor 100 to protect the fluorescent sensor and prevent light leakage.

In summarizing the above, the PCR device according to the present invention can simultaneously detect various fluorescence for a plurality of types of mass samples, as well as transfer the samples to a separate chamber partitioned according to temperature, thereby reducing thermal cycling. simplification can be achieved.

Claims (4)

A plurality of chambers having different temperature ranges,
Each of the chambers includes a transfer area in which a sample cartridge including a plurality of wells can move,
A PCR apparatus including a fluorescent sensor transfer area in which the fluorescent sensor moves to scan the sample cartridge in the lower part of the chamber in the lowest temperature section of the chambers.
According to claim 1,
a first chamber having a temperature range of 60 to 80°C; and
PCR apparatus, characterized in that consisting of a second chamber having a temperature range of 90 to 100 ℃.
3. The method of claim 2,
The fluorescent sensor is disposed under the first chamber, PCR apparatus, characterized in that for scanning the sample cartridge in the first chamber.
According to claim 1,
An opening/closing means for moving the sample cartridge between chambers is included between the plurality of chambers, and the opening/closing means is made of a heat insulating material.

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